Georgia Department of Education
Accelerated Mathematics I
Frameworks
Student Edition
Unit 7
Algebraic Investigations:
Quadratics and More, Part 3
2
nd Edition
March, 2011
Georgia Department of Education
Georgia Department of Education Accelerated Mathematics I Unit 7 2nd Edition
Georgia Department of Education
Dr. John D. Barge, State School Superintendent
March, 2011 Page 2 of 45
All Rights Reserved
Table of Contents
INTRODUCTION: ............................................................................................................ 3
Henley‟s Chocolates Learning Task .................................................................................. 8
Protein Bar Toss Learning Task: Part 2 .......................................................................... 12
Paula‟s Peaches Learning Task: Part 2 ............................................................................ 17
Just the Right Border Learning Task ............................................................................... 21
Imagining a New Number Learning Task ....................................................................... 25
Geometric Connections Learning Task ........................................................................... 36
Georgia Department of Education Accelerated Mathematics I Unit 7 2nd Edition
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Dr. John D. Barge, State School Superintendent
March, 2011 Page 3 of 45
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Accelerated Mathematics I – Unit 7
Algebraic Investigations: Quadratics and More, Part 3
Student Edition
INTRODUCTION:
The focus of the unit is developing basic algebra skills and using these in a concentrated study of
quadratic functions, equations, and inequalities. Students will apply skills developed in Units 5
and 6 to assist in working with functional models and in solving elementary quadratic, rational,
and radical equations. They will extend and apply this basic algebraic knowledge during an in-
depth study of quadratics. Through exploration of many real world situations which are
represented by quadratic functions, students are introduced to general quadratic functions in both
standard form and vertex form. Students learn to solve any quadratic equation by applying
additional factoring techniques, converting the quadratic expression to vertex form and then
extracting square roots, or using the quadratic formula. Study of the quadratic formula introduces
the complex numbers so students learn the basic arithmetic of complex numbers. Students make
connections between algebraic results and characteristics of the graphs of quadratic function and
apply this understanding in solving quadratic inequalities. They conclude the unit with an
exploration of arithmetic series; this work provides a foundation for modeling data with quadratic
functions, a topic that will be explored in Unit 8.
TOPICS
Horizontal shifts as transformations of graphs of functions
Standard and vertex form for quadratic functions
Solving quadratic equations by factoring, application of the square root property, or use of the
quadratic formula
Solving quadratic inequalities graphically and algebraically
Discriminant of a quadratic equation
The arithmetic of complex numbers in standard form
The complex plane and geometric interpretation of multiplication by i
Finite arithmetic series and formulas for their sums
ENDURING UNDERSTANDINGS (Units 5, 6 and 7):
Algebraic equations can be identities that express properties of real numbers.
There is an important distinction between solving an equation and solving an applied
problem modeled by an equation. The situation that gave rise to the equation may include
restrictions on the solution to the applied problem that eliminate certain solutions to the
equation.
Techniques for solving rational equations include steps that may introduce extraneous
solutions that do not solve the original rational equation and, hence, require an extra step of
eliminating extraneous solutions.
The graph of any quadratic function is a vertical and/or horizontal shift of a vertical stretch
or shrink of the basic quadratic function 2f x x .
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The vertex of a quadratic function provides the maximum or minimum output value of the
function and the input at which it occurs.
Understand that any equation in can be interpreted as a statement that the values of two
functions are equal, and interpret the solutions of the equation as domain values for the
points of intersection of the graphs of the two functions.
Every quadratic equation can be solved using the Quadratic Formula.
The discriminant of a quadratic equation determines whether the equation has two real
roots, one real root, or two complex conjugate roots.
The complex numbers are an extension of the real number system and have many useful
applications.
The sum of a finite arithmetic series is a quadratic function of the number of terms in the
series.
KEY STANDARDS ADDRESSED:
MA1N1. Students will represent and operate with complex numbers.
a. Write square roots of negative numbers in imaginary form.
b. Write complex numbers in the form a + bi.
c. Add, subtract, multiply, and divide complex numbers.
d. Simplify expressions involving complex numbers.
MM1A3. Students will analyze quadratic functions in the forms f(x) = ax2 + bx + c and
f(x) = a(x-h)2 + k.
a. Convert between standard and vertex form.
b. Graph quadratic functions as transformations of the function f(x) = x2.
c. Investigate and explain characteristics of quadratic functions, including domain, range,
vertex, axis of symmetry, zeros, intercepts, extrema, intervals of increase and decrease, and
rates of change.
d. Explore arithmetic series and various ways of computing their sums.
e. Explore sequences of partial sums of arithmetic series as examples of quadratic functions.
MM1A4. Students will solve quadratic equations and inequalities in one variable.
a. Solve equations graphically using appropriate technology.
b. Find real and complex solutions of equations by factoring, taking square roots, and
applying the quadratic formula.
c. Analyze the nature of roots using technology and using the discriminant.
d. Solve quadratic inequalities both graphically and algebraically, and describe the solutions
using linear inequalities.
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RELATED STANDARDS ADDRESSED:
MA1P1. Students will solve problems (using appropriate technology). a. Build new mathematical knowledge through problem solving.
b. Solve problems that arise in mathematics and in other contexts.
c. Apply and adapt a variety of appropriate strategies to solve problems.
d. Monitor and reflect on the process of mathematical problem solving.
MA1P2. Students will reason and evaluate mathematical arguments. a. Recognize reasoning and proof as fundamental aspects of mathematics.
b. Make and investigate mathematical conjectures.
c. Develop and evaluate mathematical arguments and proofs.
d. Select and use various types of reasoning and methods of proof.
MA1P3. Students will communicate mathematically. a. Organize and consolidate their mathematical thinking through communication.
b. Communicate their mathematical thinking coherently and clearly to peers, teachers, and
others.
c. Analyze and evaluate the mathematical thinking and strategies of others.
d. Use the language of mathematics to express mathematical ideas precisely.
MA1P4. Students will make connections among mathematical ideas and to other disciplines. a. Recognize and use connections among mathematical ideas.
b. Understand how mathematical ideas interconnect and build on one another to produce a
coherent whole.
c. Recognize and apply mathematics in contexts outside of mathematics.
MA1P5. Students will represent mathematics in multiple ways. a. Create and use representations to organize, record, and communicate mathematical ideas.
b. Select, apply, and translate among mathematical representations to solve problems.
c. Use representations to model and interpret physical, social, and mathematical phenomena.
UNITS 5, 6 and 7 OVERVIEW
Prior to this unit, students need to have achieved proficiency with the Grade 6 – 8 standards for
Number and Operations, with Grade 8 standards for Algebra, and with the Accelerated
Mathematics I standards addressed in Unit 1 of this course. Tasks in the unit assume an
understanding of the characteristics of functions, especially of the basic function 2f x x and of
function transformations involving vertical shifts, stretches, and shrinks, as well as reflections
across the x- and y-axes. As they work through tasks, students will frequently be required to write
mathematical arguments to justify solutions, conjectures, and conclusions, to apply the
Pythagorean Theorem and other concepts related to polygons, and to draw and interpret graphs in
the coordinate plane. They will draw on previous work with linear inequalities and on their
understanding of arithmetic sequences, both in recursive and closed form.
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March, 2011 Page 6 of 45
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The initial focus of the unit is developing students‟ abilities to perform operations with algebraic
expressions and to use the language of algebra with deep comprehension. In the study of
operations on polynomials, the special products of standard MA1A2 are first studied as product
formulas and related to area models of multiplication. This work lays the foundation for treating
these as patterns for factoring polynomials later in the unit.
The work with rational and radical expressions is grounded in work with real-world contexts and
includes a thorough exploration of the concept of average speed. The need for solving rational
equations is introduced by a topic from physical science, the concept of resistance in an electrical
circuit; other applications are also included. The presentation focuses on techniques for solving
rational equations and reinforces the topic of solving quadratic equations since rational equations
that lead to both linear and quadratic equations are included. For this unit, the denominators that
occur in the expressions are limited to rational numbers and first degree polynomials. Solution of
rational equations involving higher degree denominators is addressed in Accelerated Mathematics
III. (See standard MA3A1.) Students are also introduced to techniques for solving simple radical
equations as an application of solving equations by finding intersection points of graphs.
Applied problems that can be modeled by quadratic functions or equations are used to introduce
and motivate a thorough exploration of quadratic functions, equations, and inequalities. At first,
the quadratic equations to be solved are limited to those which are equivalent to equations of the
form x2 + bx + c = 0, and students get additional practice in adding, subtracting, and multiplying
polynomials as they put a variety of quadratic equations in this standard form. The study of
general quadratic functions starts with an applied problem that explores horizontal shift
transformations and combinations of this type of transformation with those previously studied.
Students work with quadratic functions that model the behavior of objects that are thrown in the air
and allowed to fall subject to the force of gravity to learn to factor general quadratic expressions
completely over the integers and to solve general quadratic equations by factoring. Student then
continue their study of objects in free fall to learn how to find the vertex of the graph of any
polynomial function and to convert the formula for a quadratic function from standard to vertex
form. Next students explore quadratic inequalities graphically, apply the vertex form of a
quadratic function to find real solutions of quadratic equations that cannot be solved by factoring,
and then use exact solutions of quadratic equations to give exact values for the endpoints of the
intervals in the solutions of quadratic inequalities.
After students have learned to find the real solutions of any quadratic equation, they develop the
concept of the discriminant of a quadratic equation, learn the quadratic formula, and view complex
numbers as non-real solutions of quadratic equations. Students learn to perform basic arithmetic
operations on complex numbers so that they can verify complex solutions to quadratic equations
and can understand that complex solutions exist in conjugate pairs.
The unit ends with an exploration of arithmetic series, the development of formulas for calculating
the sum of such series, and applications of the concepts to counting possible pairs from a set of
objects, to counting the number of diagonals of a polygon, and to understanding the definition of
polygonal numbers.
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Dr. John D. Barge, State School Superintendent
March, 2011 Page 7 of 45
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Algebra is the language used to discuss mathematical applications in business and social science as
well as the natural sciences, computer science, and engineering. Gaining facility with this
language is essential for every educated citizen of the twenty-first century. Throughout this unit, it
is important to:
Explain how algebraic expressions, formulas, and equations represent the geometric or physical
situation under consideration.
Find different algebraic expressions for the same quantity and that the verify expressions are
equivalent.
Make conjectures about mathematical relationships and then give both geometric and algebraic
justifications for the conjecture or use a counterexample to show that the conjecture is false.
Whenever possible, use multiple representations (algebraic, graphical, tabular, and verbal) of
concepts and explain how to translate information from one representation to another.
Use graphing by hand and graphing technology to explore graphs of functions and verify
calculations.
In discussing solutions of equations, put particular techniques for solving quadratic, radical,
and rational equations in the context of the general theory of solving equations.
In the problem solving process, distinguish between solving the equation in the mathematical
model and solving the problem.
As a final note, we observe that completing the square is a topic for Accelerated Mathematics II
and is not used in this unit.
TASKS:
The remaining content of this framework consists of student tasks or activities. The first is
intended to launch the unit. Activities are designed to allow students to build their own algebraic
understanding through exploration. Thorough Teacher‟s Guides provide solutions, discuss teaching
strategy, and give additional mathematical background to accompany each task are available to
qualified personnel via a secure web site.
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Henley’s Chocolates Learning Task
Henley Chocolates is famous for its mini chocolate truffles, which are packaged in foil covered
boxes. The base of each box is created by cutting squares
that are 4 centimeters on an edge from each corner of a
rectangular piece of cardboard and folding the cardboard
edges up to create a rectangular prism 4 centimeters deep.
A matching lid is constructed in a similar manner, but, for
this task, we focus on the base, which is illustrated in the
diagrams below.
For the base of the truffle box, paper tape is used to join the
cut edges at each corner. Then the inside and outside of the
truffle box base are covered in foil.
Henley Chocolates sells to a variety retailers and creates specific box sizes in response to requests
from particular clients. However, Henley Chocolates requires that their truffle boxes always be 4
cm deep and that, in order to preserve the distinctive shape associated with Henley Chocolates, the
bottom of each truffle box be a rectangle that is two and one-half times as long as it is wide.
1. Henley Chocolates restricts box sizes to those
which will hold plastic trays for a whole number
of mini truffles. A box needs to be at least 2
centimeters wide to hold one row of mini truffles.
Let L denote the length of a piece of cardboard
from which a truffle box is made. What value of
L corresponds to a finished box base for which
the bottom is a rectangle that is 2 centimeters
wide?
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2. Henley Chocolates has a maximum size box of mini truffles that it will produce for retail sale.
For this box, the bottom of the truffle box base is a rectangle that is 50 centimeters long. What
are the dimensions of the piece of cardboard from which this size truffle box base is made?
3. Since all of the mini truffle boxes are 4 centimeters deep, each box holds two layers of mini
truffles. Thus, the number of truffles that can be packaged in a box depends the number of
truffles that can be in one layer, and, hence, on the area of the bottom of the box. Let A(x)
denote the area, in square centimeters, of the rectangular bottom of a truffle box base. Write a
formula for A(x) in terms of the length L, in centimeters, of the piece of cardboard from which
the truffle box base is constructed.
4. Although Henley Chocolates restricts truffle box sizes to those that fit the plastic trays for a
whole number of mini truffles, the engineers responsible for box design find it simpler to study
the function A on the domain of all real number values of L in the interval from the minimum
value of L found in item 1 to the maximum value of L found in item 2. State this interval of L
values as studied by the engineers at Henley Chocolates.
The next few items depart from Henley Chocolates to explore graph transformations that will give
us insight about the function A for the area of the bottom of a mini truffle box. We will return to
the function A in item 9.
5. Use technology to graph each of the following functions on the same axes with the graph of
the function f defined by f (x) = x2. Use a new set of axes for each function listed below, but
repeat the graph of f each time. For each function listed, describe a rigid transformation of the
graph of f that results in the graph of the given function. Make a conjecture about the graph of 2
y x h , where h is any real number.
a) 2
3y x
b) 2
6y x
c) 2
8y x
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6. Use technology to graph each of the following functions on the same axes with the graph of
the function f defined by f (x) = x2. Use a new set of axes for each function listed below, but
repeat the graph of f each time. For each function listed, describe a rigid transformation of the
graph of f that results in the graph of the given function.
a) 2
2y x
b) 2
5y x
c) 2
9y x
7. We can view the exercises in item 5 as taking a function, in this case the function, f (x) = x2,
and replacing the “x” in the formula with “x – h”. We can view the exercises in item 6 as
replacing the “x” in the formula with “x + h”, but we can also view these exercises as replacing
the “x” in the formula with “x – h”.
a. How can this be done?
b. Does your conjecture from item 5 agree with the transformations you described for item 6?
If so, explain how it works. If not, adjust the statement of your conjecture to include these
examples also.
c. What do you think the will happen if we replace the “x” in the formula with “x – h” for
other functions in our basic family of functions? Have you seen any examples of such
replacements before?
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8. For each pair of functions below, predict how you think the graphs will be related and then use
technology to graph the two functions on the same axes and check your prediction.
a. 2 2 and 3y x y x
b. 223 and 3 4y x y x
c. 2 21 1 and 5
2 2y x y x
d. 220.75 and 0.75 6y x y x
e. 222 and 2 5 7y x y x
Now we return to the function studied by the engineers at Henley Chocolates.
9. Let g be the function with the same formula as the formula for function A but with domain all
real numbers. Describe the transformations of the function f , the square function, that will
produce the graph of the function g. Use technology to graph f and g on the same axes to
check that the graphs match your description of the described transformations.
10. Describe the graph of the function A in words and make a hand drawn sketch. Remember
that you found the domain of the function in item 4. What is the range of the function A?
11. The engineers at Henley Chocolates responsible for box design have decided on two new box
sizes that they will introduce for the next winter holiday season.
a. The area of the bottom of the larger of the new boxes will be 640 square centimeters.
Use the function A to write and solve an equation to find the length L of the cardboard
need to make this new box.
b. The area of the bottom of the smaller of the new boxes will be 40 square centimeters.
Use the function A to write and solve an equation to find the length L of the cardboard
need to make this new box.
12. How many mini-truffles do you think the engineers plan to put in each of the new boxes?
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Protein Bar Toss Learning Task: Part 2
In the first part of the learning task about Blake attempting to toss a protein bar to Zoe, you
found how long it took for the bar to go up and come back down to the starting height. However,
there is a question we did not consider: How high above its starting point did the protein bar go
before it started falling back down? We‟re going to explore that question now.
1. So far in Mathematics I and II, you have examined the graphs of many different quadratic
functions. Consider the functions you graphed in the Henley Chocolates task and in the first
part of the Protein Bar Toss. Each of these functions has a formula that is, or can be put in,
the form 2y ax bx c with 0a . When we consider such formulas with domain all real
numbers, there are some similarities in the shapes of the graphs. The shape of each graph is
called a parabola. List at least three characteristics common to the parabolas seen in these
graphs.
2. The question of how high the protein bar goes before it starts to come back down is related to
a special point on the graph of the function. This point is called the vertex of the parabola.
What is special about this point?
3. In the first part of the protein bar task you considered three different functions, each one
corresponding to a different cliff height. Let‟s rename the first of these functions as h1, so
that 2
1( ) 16 24 160h t t t .
a. Let 2( )h t denote the height of the protein bar if it is thrown from a cliff that is 56 feet
higher. Write the formula for the function 2h .
b. Let 3( )h t denote the height of the protein bar if it is thrown from a cliff that is 88 feet
lower. Write the formula for the function 3h .
c. Use technology to graph all three functions, h1, h2, and h3, on the same axes.
d. Estimate the coordinates of the vertex for each graph.
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e. What number do the coordinates have in common? What is the meaning of this number
in relation to the toss of the protein bar?
f. The other coordinate is different for each vertex. Explain the meaning of this number for
each of the vertices.
4. Consider the formulas for h1, h2, and h3.
a. How are the formulas different?
b. Based on your answer to part a, how are the three graphs related? Do you see this
relationship in your graphs of the three functions on the same axes? If not, restrict the
domain in the viewing window so that you see the part of each graph you see corresponds
to the same set of t-values.
5. In the introduction above we asked the question: How high above its starting point did the
protein bar go before it started falling back down?
a. Estimate the answer to the question for the original situation represented by the function h1.
b. Based on the relationship of the graphs of h2 and h3 to h1, answer the question for the
functions h2 and h3.
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Estimating the vertex from the graph gives us an approximate answer to our original question,
but an algebraic method for finding the vertex would give us an exact answer. The answers to
the questions in item 5 suggest a way to use our understanding of the graph of a quadratic
function to develop an algebraic method for finding the vertex. We‟ll pursue this path next.
6. For each of the quadratic functions below, find the y-intercept of the graph. Then find all the
points with this value for the y-coordinate.
a. 2 4 9f x x x
b. 24 8 5f x x x
c. 2 6 7f x x x
d. 2 , 0f x ax bx c a
7. One of the characteristics of a parabola graph is that the graph has a line of symmetry.
a. For each of the parabolas considered in item 6, use what you know about the graphs of
quadratic functions in general with the specific information you have about these
particular functions to find an equation for the line of symmetry.
b. The line of symmetry for a parabola is called the axis of symmetry. Explain the
relationship between the axis of symmetry and the vertex of a parabola. Then, find the x-
coordinate of the vertex for each quadratic function listed in item 6.
c. Find the y-coordinate of the vertex for the quadratic functions in item 6, parts a, b, and c,
and then state the vertex as a point.
d. Describe a method for finding the vertex of the graph of any quadratic function given in
the form 2 , 0f x ax bx c a .
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8. Return to height functions h1, h2, and h3.
a. Use the method you described in item 7, part d, to find the exact coordinates of the vertex
of each graph.
b. Find the exact answer to the question: How high above its starting point did the protein
bar go before it started falling back down?
9. Each part below gives a list of functions. Describe the geometric transformation of the graph
of first function that results in the graph of the second, and then describe the transformation
of the graph of the second that gives the graph of the third, and, where applicable, describe
the transformation of the graph of the third that yields the graph of the last function in the
list. For the last function in the list, expand its formula to the form 2f x ax bx c and
compare to the function in the corresponding part of item 6 with special attention to the
vertex of each.
a. 22 2, 5, 2 5f x x f x x f x x
b. 22 2 2, 4 , 4 9, 4 1 9,f x x f x x f x x f x x
c. 22 2 2, , 16, 3 16f x x f x x f x x f x x
10. For any quadratic function of the form 2f x ax bx c :
a. Explain how to get a formula for the same function in the form 2
f x a x h k .
b. What do the h and k in the formula of part a represent relative to the function?
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11. Give the vertex form of the equations for the functions h1, h2, and h3 and verify algebraically
the equivalence with the original formulas for the functions. Remember that you found the
vertex for each function in item 8, part a.
12. For the functions given below, put the formula in the vertex form 2
f x a x h k , give
the equation of the axis of symmetry, and describe how to transform the graph of y = x2 to
create the graph of the given function.
a. 23 12 13f x x x
b. 2 7 10f x x x
c. 22 12 24f x x x
13. Make a hand-drawn sketch of the graphs of the functions in item 12. Make a dashed line for
the axis of symmetry, and plot the vertex, y-intercept and the point symmetric with the y-
intercept.
14. Which of the graphs that you drew in item 14 have x-intercepts?
a. Find the x-intercepts that do exist by solving an appropriate equation and then add the
corresponding points to your sketch(es) from item 14.
b. Explain geometrically why some of the graphs have x-intercepts and some do not.
c. Explain how to use the vertex form of a quadratic function to decide whether the graph of
the function will or will not have x-intercepts. Explain your reasoning.
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Paula’s Peaches Revisited Learning Task
In this task, we revisit Paula, the peach grower who wanted to expand her peach orchard last
year. In the established part of her orchard, there are 30 trees per acre with an average yield of
600 peaches per tree. Data from the local agricultural experiment station indicated that if Paula
chose to plant more than 30 trees per acre in the expanded section of orchard, when the trees
reach full production several years from now, the average yield of 600 peaches per tree would
decrease by 12 peaches per tree for each tree over 30 per acre. In answering the questions below,
remember that the data is expressed in averages and does mean that each tree produces the
average number of peaches.
1. Let x be the number of trees Paula might plant per acre in her new section of orchard and let
Y(x) represent the predicted average yield in peaches per acre. Write the formula for the
function Y. Explain your reasoning, and sketch a graph of the function on an appropriate
domain.
2. Paula wanted to average at least as many peaches per acre in the new section of orchard as in
the established part.
a. Write an inequality to express the requirement that, for the new section, the average yield
of peaches per acre should be at least as many peaches as in the established section.
b. Solve the inequality graphically. Your solution should be an inequality for the number of
trees planted per acre.
c. Change your inequality to an equation, and solve the equation algebraically. How are the
solutions to the equation related to the solution of your inequality?
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3. Suppose that Paula wanted to a yield of at least 18900 peaches.
a. Write an inequality to express the requirement of an average yield of 18900 peaches per
acre.
b. Solve the equation 2 80 1575 0x x by factoring.
c. Solve the inequality from part a. Explain how and why the solutions from part b are
related to the solution of the inequality?
Solving 2 80 1575 0x x by factoring required you to find a pair of factors of 1575 with a
particular sum. With a number as large as 1575, this may have taken you several minutes. Next
we explore an alternative method of solving quadratic equations that applies the vertex form of
quadratic functions. The advantages of this method are that it can save time over solving
equations by factoring when the right factors are hard to find and that it works with equations
involving quadratic polynomials that cannot be factored over the integers.
4. Consider the quadratic function 2 80 1575f x x x .
a. What are the x-intercepts of the graph? Explain how you know.
b. Rewrite the formula for the function so that the x-intercepts are obvious from the
formula.
c. There is a third way to express the formula for the function, the vertex form. Rewrite the
formula for the function in vertex form.
d. Use the vertex form and take a square root to solve for the x-intercepts of the graph.
Explain why you should get the same answers as part a.
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e. Explain the relationship between the vertex and the x-intercepts.
5. Consider the quadratic equation 2 4 3 0x x .
a. Show that the quadratic polynomial 2 4 3x x cannot be factored over the integers.
b. Solve the equation by using the vertex form of the related quadratic function and taking a
square root.
c. Approximate the solutions to four decimal places and check them in the original
equation.
d. How are the x-intercepts and axis of symmetry related? Be specific.
6. Suppose that Paula wanted to grow at least 19000 peaches.
a. Write an inequality for this level of peach production.
b. Solve the inequality graphically.
c. Solve the corresponding equation algebraically. Approximate any non-integer solutions
to four decimal places. Explain how to use the solutions to the equation to solve the
inequality.
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7. Suppose that Paula wanted to grow at least 20000 peaches.
a. Write an inequality for this level of peach production.
b. What happens when you solve the corresponding equation algebraically?
c. Solve the inequality graphically.
d. Explain the connection between parts b and c.
The method you used to solve the equations in items 5 and 6 above can be applied to solve: 2a x + b x + c = 0 for any choice of real number coefficients for a, b, and c as long as 0a .
When this is done in general, we find that the solutions have the form 2 4
2
b b acx
aand
2 4
2
b b acx
a. This result is called the quadratic formula and usually stated in summary
form as follows.
The Quadratic Formula: If 2a x + b x + c = 0 with 0a , then
2 4
2
b b acx
a.
Using the Quadratic Formula is more straightforward and, hence, more efficient than the method
of putting the quadratic expression in vertex form and solving by taking square roots. An
upcoming task, Just the Right Border Learning Task, will explore using the Quadratic Formula
to solve quadratic equations.
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Just the Right Border Learning Task
1. Hannah is an aspiring artist who enjoys taking nature photographs with her digital camera.
Her mother, Cheryl, frequently attends estate sales in search of unique decorative items. Last
month Cheryl purchased an antique picture frame that she thinks would be perfect for
framing one of Hannah‟s recent
photographs. The frame is rather large, so
the photo needs to be enlarged. Cheryl
wants to mat the picture. One of Hannah‟s
art books suggest that mats should be
designed so that the picture takes up 50% of
the area inside the frame and the mat covers
the other 50%. The inside of the picture
frame is 20 inches by 32 inches. Cheryl
wants Hannah to enlarge, and crop if
necessary, her photograph so that it can be
matted with a mat of uniform width and, as
recommended, take up 50% of the area
inside the mat. See the image at the right.
a. Let x denote the width of the mat for the picture. Write an equation in x that models this
situation.
b. Put the equation from part a in the standard form 2 0ax bx c . Can this equation be
solved by factoring over the integers?
c. The quadratic formula can be used to solve quadratic equations that cannot be solved by
factoring over the integers. Using the simplest equivalent equation in standard form,
identify a, b, and c from the equation in part b and find 2 4b ac ; then substitute these
values in the quadratic formula to find the solutions for x. Give exact answers for x and
approximate the solutions to two decimal places.
d. To the nearest tenth of an inch, what should be the width of the mat and the dimensions
for the photo enlargement?
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2. The quadratic formula can be very useful in solving problems. Thus, it should be practiced
enough to develop accuracy in using it and to allow you to commit the formula to memory.
Use the quadratic formula to solve each of the following quadratic equations, even if you
could solve the equation by other means. Begin by identifying a, b, and c and finding 2 4b ac ; then substitute these values into the formula.
a. 24 6 0z z
b. 2 2 8 0t t
c. 23 15 12x x
d. 225 9 30w w
e. 27 10x x
f. 7
22
t
t
g. 23 2 5 23p p
h. 212 90z
3. The expression 2 4b ac in the quadratic formula is called the discriminant of the quadratic
equation in standard form. All of the equations in item 2 had values of a, b, and c that are
rational numbers. Answer the following questions for quadratic equations in standard form
when a, b, and c are rational numbers. Make sure that your answers are consistent with
the solutions from item 2.
a. What is true of the discriminant when there are two real number solutions to a quadratic
equation?
b. What is true of the discriminant when the two real number solutions to a quadratic
equation are rational numbers?
c. What is true of the discriminant when the two real number solutions to a quadratic
equation are irrational numbers?
d. Could a quadratic equation with rational coefficients have one rational solution and one
irrational solution? Explain your reasoning.
e. What is true of the discriminant when there is only one real number solution? What kind
of number do you get for the solution?
f. What is true of the discriminant when there is no real number solution to the equation?
Solve 22 1 1
3 4 6q q using the quadratic formula.
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4. There are many ways to prove the quadratic formula. One that relates to the ideas you have
studied so far in this unit comes from considering a general quadratic function of the form 2f x ax bx c , putting the formula for the function in vertex form, and then using the
vertex form to find the roots of the function. Such a proof does not require that a, b, and c be
restricted to rational numbers; a, b, and c can be any real numbers with 0a . Why is the
restriction 0a needed?
Alternate item 4
There are many ways to show why the quadratic formula always gives the solution(s) to any
quadratic equation with real number coefficients. You can work through one of these by
responding to the parts below. Start by assuming that each of a, b, and c is a real number,
that 0a , and then consider the quadratic equation 2 0ax bx c .
a. Why do we assume that 0a ?
b. Form the corresponding quadratic function, 2f x ax bx c , and put the formula for
f(x) in vertex form, expressing k in the vertex form as a single rational expression.
c. Use the vertex form to solve for x-intercepts of the graph and simplify the solution. Hint:
Consider two cases, a > 0 and a < 0, in simplifying 2a .
5. Use the quadratic formula to solve the following equations with real number coefficients.
Approximate each real, but irrational, solution correct to hundredths.
a. 2 5 1 0x x
b. 23 5 2 0q q
c. 23 11 2 33t t
d. 29 13w w
6. Verify each answer for item 5 by using a graphing utility to find the x-intercept(s) of an
appropriate quadratic function.
a. Put the function for item 5, part c, in vertex form. Use the vertex form to find the t-
intercept.
b. Solve the equation from item 5, part d, by factoring.
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7. Answer the following questions for quadratic equations in standard from where a, b, and c
are real numbers.
a. What is true of the discriminant when there are two real number solutions to a quadratic
equation?
b. Could a quadratic equation with real coefficients have one rational solution and one
irrational solution? Explain your reasoning.
c. What is true of the discriminant when there is only one real number solution?
d. What is true of the discriminant when there is no real number solution to the equation?
e. Summarize what you know about the relationship between the determinant and the
solutions of a quadratic of the form 2 0ax bx c where a, b, and c are real numbers
with 0a into a formal statement using biconditionals.
8. A landscape designer included a cloister (a rectangular garden surrounded by a covered
walkway on all four sides) in his plans for a new public park. The garden is to be 35 feet by
23 feet and the total area enclosed by the garden and walkway together is 1200 square feet.
To the nearest inch, how wide does the walkway need to be?
9. In another area of the park, there will be an open rectangular area of grass surrounded by a
flagstone path. If a person cuts across the grass to get from the southeast corner of the area to
the northwest corner, the person will walk a distance of 15 yards. If the length of the area is
5 yards more than the width, to the nearest foot, how much distance is saved by cutting
across rather than walking along the flagstone path?
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Imagining a New Number Learning Task
In other learning tasks of this unit, you encountered some quadratic equations for which the
discriminates are negative numbers. For each of these equations, there is no real number
solution because a solution requires that we find the square root of the discriminant and no real
number can be the square root of a negative number. If there were a real number answer, the
square of that number would have to be negative, but the square of every real number is greater
than or equal to zero.
The problem of taking the square root of a negative number was ignored or dismissed as
impossible by early mathematicians who encountered it. In his 1998 book, The Story of 1 ,
Paul J. Nahin describes the situation that most historians of mathematics acknowledge as the
first recorded encounter with the square root of a negative number. Nahin quotes W. W.
Beman, a professor of mathematics and mathematics historian from the University of Michigan,
in a talk he gave at an 1897 meeting of the American Association for the Advancement of
Science:
We find the square root of a negative quantity appearing for the first time in the
Stetreometria of Heron of Alexandria [c. 75 A.D.] . . . After having given a
correct formula of the determination of the volume of a frustum of a pyramid with
square base and applied it successfully to the case where the side of the lower base is
10, of the upper 2, and the edge 9, the author endeavors to solve the problem where
the side of the lower base is 28, the upper 4, and the edge 15. Instead of the square
root of 81 – 144 required by the formula, he takes the square root of 144 – 81 . . . ,
i.e., he replaces 1 by 1, and fails to observe that the problem as stated is
impossible. Whether this mistake was due to Heron or to the ignorance of some
copyist cannot be determined.
Nahin then observes that “so Heron missed being the earliest known scholar to have derived the
square root of a negative number in a mathematical analysis of a physical problem. If Heron
really did fudge his arithmetic then he paid dearly for it in lost fame.”
Nahin then reports on Diophantus of Alexandria, who most likely wrote his famous book,
Arithmetica, about the year 250 A.D. Problem 22 of book 6 of the Arithmetica posed the
question of finding the length of the legs of a right triangle with area 7 and perimeter 12,
measured in appropriate units. Diophantus reduced this problem to that of solving the quadratic
equation 2336 24 172x x . Diophantus knew a method of solving quadratic equations
equivalent to the quadratic formula, but, quoting Nahin, “What he wrote was simply that the
quadratic equation was not possible.”
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1. Follow the steps below to see how Diophantus arrived at the equation 2336 24 172x x .
a. Let a and b denote the lengths of the legs of a right triangle with area 7 and perimeter 12.
Explain why 14ab and 2 2 12a b a b .
b. Let x be a number so that 1
ax
and 14b x . Based on the meaning of a and b, explain
why there must be such a number x.
c. Replace a and b in the equation 2 2 12a b a b with the expressions in terms of x,
and write an equivalent equation with the square root expression on the left side of the
equation.
d. Square both sides of the final equation from part c and simplify to obtain Diophantus‟
equation: 2336 24 172x x .
2. What happens when you use the quadratic formula to solve 2336 24 172x x?
According to Eugene W. Hellmich writing in Capsule 76 of Historical Topics for the
Mathematics Classroom, Thirty-first Yearbook of the National Council of Teachers of
Mathematics, 1969:
The first clear statement of difficulty with the square root of a negative number was
given in India by Mahavira (c. 850), who wrote: “As in the nature of things, a
negative is not a square, it has no square root.” Nicolas Chuquet (1484) and Luca
Pacioli (1494) in Europe were among those who continued to reject imaginaries.
However, there was a break in the rejection of square roots of negative numbers in 1545 when
Gerolamo (or Girolamo) Cardano, known in English as Jerome Cardan, published his important
book about algebra, Ars Magna (Latin for “The Great Art”). Cardano posed the problem of
dividing ten into two parts whose product is 40.
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3. Note that, when Cardano stated his problem about dividing ten into two parts, he was using
the concept of “divide” in the sense of dividing a line segment of length 10 into two parts of
shorter length.
a. Show that Cardano‟s problem leads to the quadratic equation 2 10 40 0x x .
b. Find the solutions to this equation given by the quadratic formula even though they are
not real numbers.
4. Rather than reject the solutions to 2 10 40 0x x as impossible, Cardano simplified them
to obtain 5 15 and 5 15 , stated that these solutions were “manifestly impossible”,
but plunged ahead by saying “nevertheless, we will operate.” He “operated” by treating
these expressions as numbers that follow standard rules of algebra and checked that they
satisfied his original problem.
a. Assuming that these numbers follow the usual rules of algebra, verify that their sum is
10.
b. Assuming in addition that 15 15 15 ,verify that the product of the numbers is
40.
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So, Cardano was the first to imagine that there might be some numbers in addition to the real
numbers that we represent as directed lengths. However, Cardano did not pursue this idea.
According to Hellmich in his mathematics history capsule, “Cardano concludes by saying that
these quantities are „truly sophisticated‟ and that to continue working with them would be „as
subtle as it would be useless.‟” Cardano did not see any reason to continue working with the
numbers because he was unable to see any physical interpretation for numbers. However, other
mathematicians saw that they gave useful algebraic results and continued the development of
what today we call complex numbers.
Cardano‟s Ars Magna drew much attention among mathematicians of his day, not because of his
computations with the numbers 5 15 and 5 15 , but because it contained a formula,
which came to be known as the Cardan formula, for solving any cubic equation.
5. State the standard form for a general cubic equation.
a. Create some examples of cubic equations in standard form.
b. Write formulas for cubic functions whose x-intercepts are the solutions of the cubic
equations from part a.
c. Use a graphing utility to graph the functions from part b. How many x-intercepts does
each of the functions from part b have?
d. How many real number solutions does each of the equations from part a have?
The Italian engineer Rafael Bombelli continued Cardano‟s work. In some cases, Cardan‟s
formula gives roots of cubic equations expressed using the square root of a negative number. In
his book, Algebra, published in 1572, Bombelli showed that the roots of the cubic equation 3 15 4x x are 4, 2 3 , and 2 3 but observed that Cardan‟s formula expresses the root
of x = 4 as 3 3
2 121 2 121x . Quoting Nahin in The Story of 1 , “It was
Bombelli‟s great insight to see that the weird expression that Cardan‟s formula gives for x is real,
but expressed in a very unfamiliar manner.” This realization led Bombelli to develop the theory
of numbers complex numbers.
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Today we recognize Bombelli‟s “great insight,” but many mathematicians of his day (and some
into the twentieth century) remained suspicious of these new numbers. Rene Descartes, the
French mathematician who gave us the Cartesian coordinate system for plotting points, did not
see a geometric interpretation for the square root of a negative number so in his book La
Geometrie (1637) he called such a number “imaginary.” This term stuck so that we still refer to
the square root of a negative number as “imaginary.” By the way, Descartes is also the one who
coined the term “real” for the real numbers.
We now turn to the mathematics of these “imaginary” numbers.
In 1748, Leonard Euler, one of the greatest mathematicians of all times, started the use of the
notation “i” to represent the square root of – 1, that is, 1i . Thus,
2 1 1 1i ,
since i represents the number whose square is – 1.
This definition preserves the idea that the square of a square root returns us to the original
number, but also shows that one of the basic rules for working with square roots of real numbers,
for any real numbers a and b, a b ab
does not hold for square roots of negative numbers because, if that rule were applied we would
not get –1 for 2i .
6. As we have seen, the number i is not a real number; it is a new number. We want to use it to
expand from the real numbers to a larger system of numbers.
a. What meaning could we give to 2 , 3 , 4 , 5 , ...i i i i ?
b. Find the square of each of the following: 2 , 7 , 10 , 25i i i i .
c. How could we use i to write an expression for each of the following: 4, 25, 49 ?
d. What meaning could we give , 2 , 3 , 4 , 5 , ...?i i i i i
e. Write an expression involving i for each of the following: 9, 16, 81 .
7. We are now ready to be explicit about imaginary numbers. An imaginary number is any
number that can be written in the form bi , where b is an real number and 1i .
Imaginary numbers are also sometimes called pure imaginary numbers.
Write each of the following imaginary numbers in the standard form bi:
1 5, 11, , 7, 18
36 64.
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8. Any number that can be written in the form a bi , where a and b are real numbers, is called
a complex number. We refer to the form a bi as the standard form of a complex number
and call a the real part and b the imaginary part .
Write each of the following as a complex number in standard form and state its real part and
its imaginary part. 6 1, 12 100, 31 20
As defined above, the set of complex numbers includes all of the real numbers (when the
imaginary part is 0), all of the imaginary numbers (when the real part is 0), and lots of other
numbers that have nonzero real and imaginary parts.
We say that two complex numbers are equal if their real parts are equal and their imaginary parts
are equal, that is,
if a bi and c di are complex numbers,
then a bi c di if and only if a = c and b = d.
In order to define operations on the set of complex numbers in a way that is consistent with the
established operations for real numbers, we define addition and subtraction by combining the
real and imaginary parts separately:
if a bi and c di are complex numbers,
then a bi c d i a c b d i
a bi c d i a c b d i
.
9. Apply the above definitions to perform the indicated operations and write the answers in
standard form.
a. (3 5 ) (2 6 )i i
b. 5 4 3 5i i
c. 13 3i i
d. 7 9 2i
e. 5.4 8.3 3.7 4.6i i
f. 3 5 4 4
7 7 7 7i i
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To multiply complex numbers, we use the standard form of complex numbers, multiply the
expressions as if the symbol i were an unknown constant, and then use the fact that 2 1i to
continue simplifying and write the answer as a complex number in standard form.
10. Perform each of the following indicated multiplications, and write your answer as a complex
number in standard form.
a. 6 2i i
b. 2 3 4i i
c. 2
9 67
i
Note writing i in front of an imaginary
part expressed as a root is standard
practice to make the expression easier to
read.
d. 4 13 2 13i i --
e. 5 5i i
f. 6 12
11. For each of the following, use substitution to determine whether the complex number is a
solution to the given quadratic equation.
a. Is 2 3i a solution of 2 4 13 0x x ? Is 2 3i a solution of this same equation?
b. Is 2 i a solution of 2 3 3 0x x ? Is 2 i a solution of this same equation?
12. Find each of the following products.
a. 1 1i i
b. 5 2 5 2i i
c. 7 8 7 8i i
d. 1 2 1 2
2 3 2 3i i
e. 4 6 4 6i i
13. The complex numbers a bi and a bi are called complex conjugates. Each number is
considered to be the complex conjugate of the other.
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a. Review the results of your multiplications in item 12, and make a general statement that
applies to the product of any complex conjugates.
b. Make a specific statement about the solutions to a quadratic equation in standard form
when the discriminant is a negative number.
So far in our work with operations on complex numbers, we have discussed addition,
subtraction, and multiplication and have seen that, when we start with two complex numbers in
standard form and apply one of these operations, the result is a complex number that can be
written in standard.
14. Now we come to division of complex numbers. Consider the following quotient: 2 3
3 4
i
i.
This expression is not written as a complex number in standard form; in fact, it is not even
clear that it can be written in standard form. The concept of complex conjugates is the key to
carrying out the computation to obtain a complex number in standard form.
a. Find the complex conjugate of 3 4i , which is the denominator of 2 3
3 4
i
i.
b. Multiply the numerator and denominator of 2 3
3 4
i
iby the complex conjugate from part a.
c. Explain why 2 3 2 3 3 4
3 4 3 4 3 4
i i i
i i i and then use your answers from part b obtain
18 1
25 25i as the complex number in standard form equal to the original quotient.
d. For real numbers, if we multiply the quotient by the divisor we obtain the dividend. Does
this relationship hold for the calculation above?
15. Use the same steps as in item 14 to simplify each of the following quotients and give the
answer as a complex number in standard form.
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a. 5 6
5 6 22
ii i
i
b. 3 2
7 2i
c. 14 2
2
i
i
d. 2 8
5 18
Item 15 completes our discussion of basic numerical operations with complex numbers. In our
discussion of the early history of the development of complex numbers, we noted that Cardano
did not continue work on complex numbers because he could not envision any geometric
interpretation for them. It was over two hundred years until, in 1797, the Norwegian surveyor
Caspar Wessel presented his ideas for a very simple geometric model of the complex numbers.
For the remainder of the task you will investigate the modern geometric representation of
complex numbers, based on Wessel‟s work and that of Wallis, Argand, Gauss, and other
mathematicians, some of whom developed the same interpretation as Wessel independently.
In representing the complex numbers geometrically, we begin with a number line to represent the
pure imaginary numbers and then place this number line perpendicular to a number line for the
real numbers. The number 0i = 0 is both imaginary and real, so it should be on both number
lines. Therefore, the two number lines are drawn perpendicular and intersecting at 0, just as we
do in our standard coordinate system. Geometrically, we represent the complex number a bi by
the point (a, b) in the coordinate system. When we use this representation, we refer to a complex
number as a point in the complex number plane. Note that this is a very different interpretation
for points in a plane that the one we use for graphing functions whose domain and range are
subsets of the real numbers as we did in considering cubic functions in item 5.
Use a complex number plane to graph and label each of the following complex numbers: 2 3i ,
8 6i , 5i , – 2, 7 3i , 6 i , 3 4i , 3.5
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16. Geometrically, what is the meaning of the absolute value of a real number? We extend this
idea and define the absolute value of the complex number a bi to be the distance in the
complex number plane from the number to zero. We use the same absolute value symbol as
we did with real numbers so that a bi represents the absolute value of the complex
number a bi .
a. Find the absolute value of each of the complex numbers plotted in item 16.
b. Verify your calculations from part a geometrically.
c. Write a formula in terms of a and b for calculating a bi .
d. What is the relationship between the absolute value of a complex number and the
absolute value of its conjugate? Explain.
e. What is the relationship between the absolute value of a complex number and the product
of that number with its conjugate? Explain.
17. The relationship you described in part e of item 17 is a specific case of a more general
relationship involving absolute value and products of complex numbers. Find each of the
following products of complex numbers from item 16 and compare the absolute value of
each product to the absolute values of the factors in the product. (Note that you found the
length of each of the factors below in item 17, part a.) Finally, make and prove a conjecture
about the absolute value of the product of two complex numbers.
a. 2 3 7 3i i
b. 3 4 5i i
c. 2 8 6i
d. 6 3.5i
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18. By definition, 1i i and
2 1i .
a. Find 3 4 5 12, , , . . .,i i i i . What pattern do you observe?
b. How do the results of your calculations of powers of i relate to item 18?
c. Devise a way to find any positive integer power of i , and use it to find the following
powers of i: 26 55 136 373, , ,i i i i .
19. We conclude this task with an exploration of the geometry of multiplying a complex number
by i .
a. Graph 2 3 4, , ,i i i i in the complex number plane. How does the point move each time it
is multiplied by i ?
b. Let 5 12z i . What is i z ?
c. Plot each of the complex numbers in part b and draw the line segment connecting each
point to the origin.
d. Explain why multiplying by i does not change the absolute value of a complex number.
e. What geometric effect does multiplying by i seem to have on a complex number? Verify
your answer for the number z from part b.
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Geometric Connections Learning Task
Scenario 1: A group of college freshmen attend a freshmen orientation session. Each is given a
numbered “Hello” nametag. Students are told to shake hands with every other student there, and
they do. How many handshakes are exchanged?
Scenario 2: An airline has several hub cities and flies daily non-stop flights between each pair
of these cities. How many different non-stop routes are there?
Scenario 3: A research lab has several computers that share processing of important data. To
insure against interruptions of communication, each computer is connected directly to each of the
other computers. How many computer connections are there?
The questions asked at the end of the scenarios are really three specific versions of the same
purely mathematical question: Given a set of objects, how many different pairs of objects can
we form? One of the easiest ways to approach this problem involves thinking geometrically.
The objects, whether they are college freshmen, cities, computers, etc., can be represented as
points, and each pairing can be represented by drawing a line segment between the points. Such
a representation is called a vertex-edge graph. You will explore vertex-edge graphs further in
Mathematics III, but for now our focus is counting pairs of objects.
1. Use a vertex-edge graph and an actual count of all possible edges between pairs of points to
fill in the table below. When there are more than two vertices, it helps to arrange the points
as if they are vertices of regular polygons as shown in the table.
Number of points/vertices 1 2 3 4 5
Example diagram of vertices
Number of line segments/edges
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2. Our goal is to find a formula that gives the number of pairs of objects as a function of n, the
number of objects to be paired. Before we try to find the general formula, let‟s find the
answers for a few more specific values.
a. Draw a set of 6 points and all possible edges among 5 of the points. How many edges do
you have so far? How many additional edges do you draw to complete the diagram to
include all possible edges between two points? What is the total number of edges?
b. Draw a set of 7 points and all possible edges among 6 of the points. How many edges do
you have so far? How many additional edges do you draw to complete the diagram to
include all possible edges between two points? What is the total number of edges?
c. We are trying to find a formula for the number of pairs of objects as a function of the
number of objects. What is the domain of this function? Why does this domain allow us
to think of the function as a sequence?
d. Denote the number of pairs of n objects by pn, so that the sequence is 1 2 3, , ,p p p .
Remember that a recursive sequence is one that is defined by giving the value of at least
one beginning term and then giving a recursive relation that states how to calculate the
value of later terms based on the value(s) of one or more earlier terms. Generalize the
line of reasoning from parts a and b to write a recursive definition of the sequence
1 2 3, , ,p p p . Which beginning term(s) do you need to specify explicitly? What is the
recursive relation to use for later terms?
e. Use your recursive definition to complete the table below and verify that it agrees with
the previously found values.
n 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
pn
f. Explain how the recursive definition of 1 2 3, , ,p p p also leads to expressing pn as a
sum of integers.
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3. The numbers in the sequence 2 3 4, ,p p p are known as the triangular numbers, so called
because that number of dots can be arranged in a triangular pattern as shown below. (Image
from Weisstein, Eric W. "Triangular Number." From MathWorld--A Wolfram Web Resource.
http://mathworld.wolfram.com/TriangularNumber.html )
a. The standard notation for the triangular numbers is 1 2 3, , ,T T T . Through exploration
of patterns and/or geometric representations of these numbers, find a closed form formula
for the nth
triangular number, Tn.
b. Explain the relationship between the sequences 1 2 3, , ,p p p and 1 2 3, , ,T T T .
c. Use the relationship explained in part b to write a closed form formula for pn
4. Now we return to the scenarios.
a. In Scenario 1, if there are 40 students at the orientation session, how many handshakes
are exchanged?
b. In Scenario 2, if there are 190 airline routes between pairs of cities, how many cities are
there in the group of hub cities?
c. In Scenario 3, if there are 45 computer connections, how many computers does the
research lab use?
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The formula you found in item 3, part d, and then applied in answering the questions of item 4, is
well-known as the formula for counting combinations of n objects taken two at a time. We‟ll
next explore another counting problem with geometric connections.
5. Remember that a diagonal of a polygon is a segment that connects non-
adjacent vertices of a polygon. For example, in the quadrilateral ABCD, AC
and BD are the diagonals.
a. Based on the definition above, complete the table below.
Number of sides/vertices in the polygon 3 4 5 6 7 8 9 n
Number of diagonals from each vertex
Total number of diagonals in the polygon
b. The last entry in the table provides a formula for the total number of diagonals in a
polygon with n sides. Explain your reasoning for this formula.
6. Let 0 1 2, , ,d d d denote the sequence such that kd is number of diagonals in a polygon with
k + 3 sides.
a. Use the table form item 5, part a, to give the values for the first seven terms of the
sequence: 0 1 2 3 4 5 6, , , , , ,d d d d d d d .
b. We next seek a recursive definition of the sequence 0 1 2, , ,d d d . This recursive
definition requires understanding another sequence known as the sequence of first
differences. To aid our discussion of this other sequence, let 1f denote the value added to
0d to obtain 1d , let 2f denote the value added to 1d to obtain 2d , let 3f denote the value
added to 2d to obtain 3d , and so forth. Give the values for the first six terms of the
sequence 1 2 3, , ,f f f .
c. The sequence 1 2 3, , ,f f f is an arithmetic sequence. Explain why.
d. The standard formula for the kth
term of an arithmetic sequence is 1a k d , where a
is the first term and d is the common difference. What are a and d for the sequence
1 2 3, , ,f f f ? Write a formula for the kth
term of the sequence.
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e. Write a recursive definition for the kth
term of the sequence 0 1 2, , ,d d d .
f. Explain why, for 1,k we have the relationship that 1 2k kd f f f .
g. Use your formula for the number of diagonals of a polygon with n sides to write a
formula for kd .
h. Combine parts f and g to write a formula for sum of the first k terms of the sequence
1 2 3, , ,f f f .
7. So far in this task, you‟ve worked with two formulas: one that gives the number of
combinations of n objects taken 2 at a time and the other that counts the number of diagonals
of a polygon with n sides. Since the first formula also gives the numbers of edges in the
vertex-edge graph containing n vertices and all possible edges, there is a relationship between
the two formulas. Explain the relationship geometrically and algebraically.
8. Each of the formulas studied so far provides a way to calculate certain sums of integers. One
of the formulas sums the terms of the arithmetic sequence 1 2 3, , ,f f f . Look back at the
sequence 1 2 3, , ,p p p from items 2 and 3.
a. What is the sequence of first differences for the sequence 1 2 3, , ,p p p ?
b. Is the sequence of first differences arithmetic? Explain.
c. What does this tell you about each term of the sequence 1 2 3, , ,p p p relative to
arithmetic series?
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In item 3, we recalled that summing up the terms of the sequence 1, 2, 3, … gives the triangular
numbers, so called because that number of dots can be arranged in a triangular pattern as shown
below. (Image from Weisstein, Eric W. "Triangular Number." From MathWorld--A Wolfram Web
Resource. http://mathworld.wolfram.com/TriangularNumber.html )
The sequence 1, 2, 3, … starts with 1 and adds 1 each time. Next we consider what happens if
we start with 1 and add 2 each time.
9. The sequence that starts with 1 and adds 2 each time is very familiar sequence.
a. List the first five terms of the sequence and give its common mathematical name.
b. Why is the sequence an arithmetic sequence?
c. Complete the table below for summing terms of this sequence.
Number of terms to be summed Indicated sum of terms Value of the sum
1 1 1
2 1 + 3
3
4
5
6
d. Give a geometric interpretation for the sums in the table.
e. Fill in the last row of the table above when the number of terms to be summed is n,
including a conjecture about the value for the last column. Use “. . . “ in the indicated
sum but include an expression, in terms of n, for the last term to be summed.
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Our next goal is justification of the conjecture you just made in item 9, part e. However, rather
than work on this specific problem, it just as easy to consider summing up any arithmetic
sequence. The sum of the terms of a sequence is called a series so, as we proceed, we‟ll be
exploring closed form formulas for arithmetic series.
10. Let a and d be real numbers and let 1 2 3, , ,a a a be the arithmetic sequence with first term a
and common difference d. We‟ll use some standard notation for distinguishing between a
sequence and the corresponding series which sums the terms of the sequence.
a. Fill in the table below with expressions in terms of a and d.
Term of the sequence Expression using a and d
1a
2a
3a
4a
5a
6a
b. Let 1 2 3, , ,s s s be the sequence defined by the following pattern:
1 1
2 1 2
3 1 2 3
4 1 2 3 4
s a
s a a
s a a a
s a a a a
. . .
1 2n ns a a a
Conjecture and prove a closed form formula for the arithmetic series ns .
c. Use the sum of an arithmetic series formula to verify the conjecture for the sum of the
arithmetic series in item 9.
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11. Next we‟ll explore a different approach to a closed form formula for arithmetic series, one
that is quite useful we are examining the type of series that occurs in a problem like the
following. (This item is adapted from the “Common Differences” Sample Secondary Task
related to K-12 Mathematics Benchmarks of The American Diploma Project, copyright 2007,
Charles A. Dana Center at the University of Texas at Austin.)
Sam plays in the marching band and is participating in the fund raiser to finance
the spring trip. He‟s taking orders for boxes of grapefruit to be delivered from a
Florida grove just in time for the Thanksgiving and Christmas holiday season.
With the help of his parents and grandparents, he is trying to win the prize for
getting the most orders. The number of orders he got for each day of the last
week are, respectively, 11, 15, 19, 23, 27, 31, 35. What is the total number of
orders?
a. The total number of orders is the arithmetic series 11 15 19 23 27 31 35 . The
numbers in the corresponding arithmetic sequence are plotted on a number line below.
Find a shortcut for finding the sum of these seven terms. State your shortcut as a
mathematical conjecture, and give a justification that your conjecture works.
b. Test your conjecture from part a on an arithmetic series with exactly 5 terms. Does it
work for a series with exactly 9 terms? Does your conjecture apply to a series with
exactly 6 terms?
c. Modify your conjecture, if necessary, so that it describes a general method for finding
any finite sum of consecutive terms from an arithmetic sequence. Give a justification
that your method will always work.
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In addition to the well known triangular and square numbers, there are polygonal numbers
corresponding to each type of polygon. The names relate to the figures that can be made from
that number of dots. For example, the first five pentagonal, hexagonal, and heptagonal numbers
are shown below.
(Image from Weisstein, Eric W. "Pentagonal Number." From MathWorld--A Wolfram Web Resource.
http://mathworld.wolfram.com/PentagonalNumber.html )
(Image from Weisstein, Eric W. "Hexagonal Number." From MathWorld--A Wolfram Web Resource.
http://mathworld.wolfram.com/HexagonalNumber.html )
(Image from Weisstein, Eric W. "Heptagonal Number." From MathWorld--A Wolfram Web Resource.
http://mathworld.wolfram.com/HeptagonalNumber.html )
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March, 2011 Page 45 of 45
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12. As shown above, the number 1 is considered to be a polygonal number for each size polygon.
The actual numbers in the sequence of each type of polygonal numbers are sums of an
arithmetic series; for example, the nth
triangular number is the sum of the arithmetic series
1 2 n . Use your knowledge of arithmetic sequences and series and of polygonal
numbers complete the table below.
Polygonal
number
name
First five terms
of the sequence
of such numbers
Arithmetic sequence
whose terms sum to
form the numbers
Values
of a, d
Formula for nth
polygonal number
triangular
square
pentagonal
hexagonal
heptagonal
octagonal
13. In 2001, the owner of two successful restaurants in south metropolitan Atlanta developed a
long term expansion plan that led to the opening of five more restaurants in 2002. In 2003,
eight new restaurants opened; in 2004, eleven new restaurants opened. Assume that the
owner continued with this plan of increasing the number of new restaurants by three each
year.
a. How many restaurants did the owner have in operation by the end of 2007?
b. If the owner continues with this plan, in what year will the 500th
restaurant open?